Java程序辅导

Middleware
Middleware
2Distributed ApplicationsDistributed Applications
Operating System CommsOperating System Comms
NetworkNetwork
Introduction to Middleware I
• What is Middleware?
– Layer between OS and distributed applications
– Hides complexity and heterogeneity of distributed system 
– Bridges gap between low-level OS communications and programming 
language abstractions
– Provides common programming abstraction and infrastructure for 
distributed applications
– Overview at:  http://www.middleware.org
Distributed Applications
Middleware
Operating System Comms
(packets, bits, …)
(remote calls, object invocation, 
messages, …)
(sockets, IP, TCP, UDP, …)
Network
Middleware
3Introduction to Middleware II
• Middleware provides support for (some of):
– Naming, Location, Service discovery, Replication 
– Protocol handling, Communication faults, QoS
– Synchronisation, Concurrency, Transactions, Storage
– Access control, Authentication
• Middleware dimensions:
– Request/Reply vs. Asynchronous Messaging
– Language-specific vs. Language-independent
– Proprietary vs. Standards-based
– Small-scale vs. Large-scale
– Tightly-coupled vs. Loosely-coupled components
Middleware
4Outline
• Part I: Remote Procedure Call (RPC)
– Historic interest, but still ubiquitous
• Part II: Object-Oriented Middleware (OOM)
– Java RMI
– CORBA
– Reflective Middleware
• Part III: Message-Oriented Middleware (MOM)
– Java Message Service
– IBM MQSeries
– Web Services
• Part IV: Event-Based Middleware
– Cambridge Event Architecture
– Hermes
Middleware
5Part I: Remote Procedure Call (RPC)
• Masks remote function calls as being local
• Client/server model
• Request/reply paradigm usually implemented with 
message passing in RPC service
• Marshalling of function parameters and return value
Caller RPC Service RPC Service Remote
Function
call(…)
1) Marshal args
2) Generate ID
3) Start timer 4) Unmarshal
5) Record ID
6) Marshal
7) Set timer
8) Unmarshal
9) Acknowledge
fun(…)
message
Middleware
6Properties of RPC
Language-level pattern of function call
• easy to understand for programmer
Synchronous request/reply interaction
• natural from a programming language point-of-view
• matches replies to requests
• built in matching of requests and replies
Distribution transparency (in the no-failure case)
• hides the complexity of a distributed system
Various reliability guarantees
• deals with some distributed systems aspects of failure
Middleware
7Failure Modes of RPC
• Invocation semantics supported by RPC in the light of:
network and/or server congestion, 
client, network and/or server failure 
note DS independent failure modes
• RPC systems differ, many examples, local Cambridge thing was 
Mayflower
Exactly once (RPC system retries a few times)
• Hard error return – some failure most likely
note that “exactly once” cannot be guaranteed 
Maybe or at most once (RPC system tries once)
• Error return – programmer may retry
Middleware
8Disadvantages of RPC
 Synchronous request/reply interaction
• tight coupling between client and server
• client may block for a long time if server loaded
leads to multi-threaded programming at client
• slow/failed clients may delay servers when replying 
multi-threading essential at servers
 Distribution Transparency
• Not possible to mask all problems
 RPC paradigm is not object-oriented
• invoke functions on servers as opposed to methods on objects
fork(…)
join(…)
remote call
Middleware
9Part II: Object-Oriented Middleware (OOM)
• Objects can be local or remote
• Object references can be local or remote
• Remote objects have visible remote interfaces
• Masks remote objects as being local using proxy objects
• Remote method invocation
object A
proxy 
object B
OOM OOM
skeleton 
object B
object B
local remote
object
request
broker
/
object
manager
object
request
broker
/
object
manager
Middleware
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Properties of OOM
Support for object-oriented programming model
– objects, methods, interfaces, encapsulation, …
– exceptions (were also in some RPC systems e.g. Mayflower)
Synchronous request/reply interaction
– same as RPC
Location Transparency
– system (ORB) maps object references to locations
Services comprising multiple servers are easier to build with OOM
– RPC programming is in terms of server-interface (operation)
– RPC system looks up server address in a location service
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11
Java Remote Method Invocation (RMI)
• Distributed objects in Java
public interface PrintService extends Remote {
int print(Vector printJob) throws RemoteException;
}
• RMI compiler creates proxies and skeletons
• RMI registry used for interface lookup
• Entire system written in Java (single-language system; 
other languages can be made to work with varying 
amounts of pain)
Middleware
12
CORBA
• Common Object Request Broker Architecture
– Open standard by the OMG (Version 3.0)
– Language- and platform independent
• Object Request Broker (ORB)
– General Inter-ORB Protocol (GIOP) for communication
– Interoperable Object References (IOR) contain object location
– CORBA Interface Definition Language (IDL)
• Stubs (proxies) and skeletons created by IDL compiler
– Dynamic remote method invocation
• Interface Repository
– Querying existing remote interfaces
• Implementation Repository
– Activating remote objects on demand
Middleware
13
CORBA IDL
• Definition of language-independent remote interfaces
– Language mappings to C++, Java, Smalltalk, …
– Translation by IDL compiler
• Type system
– basic types: long (32 bit), 
long long (64 bit), short, 
float, char, boolean, 
octet, any, …
– constructed types: struct, union, sequence, array, enum
– objects (common super type Object)
• Parameter passing
– in, out, inout
– basic & constructed types passed by value
– objects passed by reference
typedef sequence Files;
interface PrintService : Server {
void print(in Files printJob);
};
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CORBA Services (selection)
• Naming Service
– Names  remote object references
• Trading Service
– Attributes (properties)  remote object references
• Persistent Object Service
– Implementation of persistent CORBA objects
• Transaction Service
– Making object invocation part of transactions
• Event Service and Notification Service
– In response to applications‘ need for asynchronous communication
– built above synchronous communication with push or pull options 
– not an integrated programming model with general IDL messages
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15
Disadvantages of OOM
 Synchronous request/reply interaction only
• So CORBA oneway semantics added and Asynchronous Method 
Invocation (AMI)
• But implementations may not be loosely coupled
 Distributed garbage collection
• Releasing memory for unused remote objects
 OOM rather static and heavy-weight
• Bad for ubiquitous systems and embedded devices
Middleware
16
OOM experience
Keynote address at Middleware 2009
Steve Vinoski
From Middleware Implementor to Middleware User
(There and back again)
Available from the course materials page
Middleware
17
Reflective Middleware
• Flexible middleware (OOM) for mobile and context-aware 
applications – adaptation to context through monitoring
and substitution of components
• Interfaces for reflection
– Objects can inspect middleware behaviour
• Interfaces for customisability
– Dynamic reconfiguration depending on environment
– Different protocols, QoS, ...
– e.g. use different marshalling strategy over unreliable wireless link
Middleware
18
Part III: Message-Oriented Middleware (MOM)
Communication using messages
Messages stored in message queues
message servers decouple client and server
Various assumptions about message content
Client App.
local message
queues
Server App.
local message
queues
message
queues
Network Network Network
Message Servers
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19
Properties of MOM
Asynchronous interaction
– Client and server are only loosely coupled
– Messages are queued
– Good for application integration
Support for reliable delivery service
– Keep queues in persistent storage
Processing of messages by intermediate message server(s)
– May do filtering, transforming, logging, …
– Networks of message servers
Natural for database integration
Middleware
20
IBM WebSphere MQ
• One-to-one reliable message passing using queues
– Persistent and non-persistent messages
– Message priorities, message notification
• Queue Managers
– Responsible for queues
– Transfer messages from input to output queues 
– Keep routing tables
• Message Channels
– Reliable connections between queue managers
• Messaging API: MQopen Open a queue
MQclose Close a queue
MQput Put message into opened queue
MQget Get message from local queue
Middleware
21
Java Message Service (JMS)
• API specification to access MOM implementations
• Two modes of operation *specified*:
– Point-to-point
• one-to-one communication using queues
– Publish/Subscribe
• cf. Event-Based Middleware
• JMS Server implements JMS API
• JMS Clients connect to JMS servers
• Java objects can be serialised to JMS messages
• A JMS interface has been provided for MQ
• pub/sub (one-to-many) - just a specification?
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22
Disadvantages of MOM
 Poor programming abstraction (but has evolved)
• Rather low-level
• Request/reply difficult to achieve, but can be done 
Message formats originally unknown to middleware
• No type checking (JMS addresses this – implementation?)
 Queue abstraction only gives one-to-one communication
• Limits scalability (JMS pub/sub – implementation?)
Middleware
23
Web Services
• Use well-known web standards for distributed computing
Communication
• Message content expressed in XML
• Simple Object Access Protocol (SOAP)
– Lightweight protocol for sync/async communication
Service Description
• Web Services Description Language (WSDL)
– Interface description for web services
Service Discovery
• Universal Description Discovery and Integration (UDDI)
– Directory with web service description in WSDL
Middleware
24
Properties of Web Services
Language-independent and open standard
SOAP offers OOM and MOM-style communication:
• Synchronous request/reply like OOM
• Asynchronous messaging like MOM
• Supports internet transports (http, smtp, ...)
• Uses XML Schema for marshalling types to/from programming 
language types
WSDL says how to use a web service
UDDI helps to find the right web service
• Exports SOAP API for access
Middleware
25
Disadvantages of Web Services
 Low-level abstraction
• leaves a lot to be implemented 
 Interaction patterns have to be built 
• one-to-one and request-reply provided
• one-to-many?
• still synchronous service invocation, rather than notification
• no nested/grouped invocations, transactions, ... 
 No location transparency
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What we lack, so far
 General interaction patterns
• we have one-to-one and request-reply
• one-to-many? many to many?
• notification?
• dynamic joining and leaving?
 Location transparency
• anonymity of communicating entities
 Support for pervasive computing
• data values from sensors
• lightweight software
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Part IV: Event-Based Middleware a.k.a. Publish/Subscribe
• Publishers (advertise and) publish events (messages)
• Subscribers express interest in events with subscriptions
• Event Service notifies interested subscribers of published events
• Events can have arbitrary content (typed) or name/value pairs
Event Service
(event-broker
network)
Subscriber
Subscriber
Subscriber
Publisher
Publisher
Publisher
publish
publish
publish
subscribe
subscribe
subscribe
notify
notify
notify
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Topic-Based and Content-Based Pub/Sub
• Event Service matches events against subscriptions
• What do subscriptions look like?
Topic-Based Publish/Subscribe
– Publishers publish events belonging to a topic or subject
– Subscribers subscribe to a topic
subscribe(PrintJobFinishedTopic, …)
(Topic and) Content-Based Publish/Subscribe
– Publishers publish events belonging to topics and 
– Subscribers provide a filter based on content of events
subscribe(type=printjobfinished, printer=‘aspen’, …)
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29
Properties of Publish/Subscribe
Asynchronous communication
• Publishers and subscribers are loosely coupled
Many-to-many interaction between pubs. and subs.
• Scalable scheme for large-scale systems
• Publishers do not need to know subscribers, and vice-versa
• Dynamic join and leave of pubs, subs, (brokers - see lecture DS-8)
(Topic and) Content-based pub/sub very expressive
• Filtered information delivered only to interested parties
• Efficient content-based routing through a broker network  
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Composite Event Detection (CED)
Content-based pub/sub may not be expressive enough
Potentially thousands of event types (primitive events)
Subscribers interest: event patterns (define high-level events,  ref DS-2)
Event Patterns
PrinterOutOfPaperEvent or PrinterOutOfTonerEvent
Composite Event Detectors (CED)
Subscribe to primitive events and publish composite events
Publisher
Publisher
Publisher
CED
CED
CED
Publisher
Subscriber
Subscriber
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Summary
• Middleware is an important abstraction for building 
distributed systems
• Synchronous vs. asynchronous communication
• Scalability, many-to-many communication
• Language integration
• Ubiquitous systems, mobile systems
1. Remote Procedure Call
2. Object-Oriented Middleware
3. Message-Oriented Middleware
4. Event-Based Middleware
Middleware